Phenylalanine and tryptophan scanning mutagenesis of CYP3A4 substrate recognition site residues and effect on substrate oxidation and cooperativity.

Phenylalanine and/or tryptophan scanning mutagenesis was performed at 15 sites within CYP3A4 proposed to be involved in substrate specificity or cooperativity. The sites were chosen on the basis of previous studies or from a comparison with the structure of P450(eryF) containing two molecules of androstenedione. The function of the 25 mutants was assessed in a reconstituted system using progesterone, testosterone, 7-benzyloxy-4-(trifluoromethyl)coumarin (7-BFC), and alpha-naphthoflavone (ANF) as substrates. CYP3A4 wild type displayed sigmoidal kinetics of ANF 5,6-oxide formation and 7-BFC debenzylation. Analysis of 12 mutants with significant steroid hydroxylase activity showed a lack of positive correlation between ANF oxidation and stimulation of progesterone 6beta-hydroxylation by ANF, indicating that ANF binds at two sites within CYP3A4. 7-BFC debenzylation was stimulated by progesterone and ANF, and 7-BFC did not inhibit testosterone or progesterone 6beta-hydroxylation. Correlational analysis showed no relationship between 7-BFC debenzylation and either progesterone or testosterone 6beta-hydroxylation. These data are difficult to explain with a two-site model of CYP3A4 but suggest that three subpockets exist within the active site. Interestingly, classification of the mutants according to their ability to oxidize the four substrates utilized in this study suggested that substrates do bind at preferred locations in the CYP3A4 binding pocket.

Identification and functional characterization of eight CYP3A4 protein variants.

The genetic component of the inter-individual variability in CYP3A4 activity has been estimated to be between 60% and 90%, but the underlying genetic factors remain largely unknown. A study of 213 Middle and Western European DNA samples resulted in the identification of 18 new CYP3A4 variants, including eight protein variants. A total of 7.5% of the population studied was found to be heterozygous for one of these variants. In a bacterial heterologous expression system, two mutants, R130Q and P416L, did not result in detectable P450 holoprotein. One mutant, T363M, expressed at significantly lower levels than wild-type CYP3A4. G56D, V170I, D174H and M445T were not significantly different when compared with wild-type CYP3A4 in expression or steroid hydroxylase activity. L373F displayed a significantly altered testosterone metabolite profile and a four-fold increase in the Km value for 1'-OH midazolam formation. The results suggest a limited contribution of CYP3A4 protein variants to the inter-individual variability of CYP3A4 activity in Caucasians. Some variants may, however, play a role in the atypical response to drugs or altered sensitivity to carcinogens.

Dual role of human cytochrome P450 3A4 residue Phe-304 in substrate specificity and cooperativity.

The structural basis of cooperativity of progesterone hydroxylation catalyzed by human cytochrome P450 3A4 has been investigated. A recent study suggested that substitution of larger side chains at positions Leu-211 and Asp-214 partially mimics the action of effector by reducing the size of the active site. Based on predictions from molecular modeling that Phe-304 in the highly conserved I helix is involved in both effector and substrate binding, a tryptophan residue was substituted at this position. The purified F304W mutant displayed hyperbolic progesterone hydroxylase kinetics, indicating a lack of homotropic cooperativity. However, the mutant remained responsive to stimulation by alpha-naphthoflavone, exhibiting a 2-fold decrease in the K(m) value for progesterone 6beta-hydroxylation in the presence of 25 microM effector. Combining substitutions to yield the triple mutant L211F/D214E/F304W maintained the V(max) and decreased the K(m) for progesterone 6beta-hydroxylation, minimized stimulation by alpha-naphthoflavone, and decreased the rate of alpha-naphthoflavone oxidation to one-eighth of the wild type. Interestingly, the DeltaA(max) for spectral binding of alpha-naphthoflavone was unaltered in L211F/D214E/F304W. Overall, the results suggest that progesterone and alpha-naphthoflavone are oxidized at separate locations within the P450 3A4 binding pocket, although both substrates appear to have equal access to the reactive oxygen.

2,2',3,3',6,6'-hexachlorobiphenyl hydroxylation by active site mutants of cytochrome P450 2B1 and 2B11.

The structural basis of species differences in cytochrome P450 2B-mediated hydroxylation of 2,2',3,3',6,6'-hexachlorobiphenyl (236HCB) was evaluated by using 14 site-directed mutants of cytochrome P450 2B1 and three point mutants of 2B11 expressed in Escherichia coli. To facilitate metabolite identification, seven possible products, including three hydroxylated and four dihydroxylated hexachlorobiphenyls, were synthesized by direct functionalization of precursors and Ullmann and crossed Ullmann reactions. HPLC and GC/MS analysis and comparison with authentic standards revealed that 2B1, 2B11, and all their mutants produced 4, 5-dihydroxy-236HCB and 5-hydroxy-236HCB, while 2B11 L363V and 2B1 I114V mutants also catalyzed hydroxylation at the 4-position. The amount of products formed by 2B1 mutants I114V, F206L, L209A, T302S, V363A, V363L, V367A, I477A, I477L, G478S, I480A, and I480L was smaller than that of the wild type. I477V exhibited unaltered 236HCB metabolism, and I480V produced twice as much dihydroxy product as the wild type. For 2B11, substitution of Val-114 or Asp-290 with Ile decreased the product yields. Replacement of Leu-363 with Val dramatically altered the profile of 236HCB metabolites. In addition to an increase in the overall level of hydroxylation, the mutant mainly catalyzed hydroxylation at the 4-position. Incubation of P450 2B1 with 5-hydroxy-236HCB produced 4,5-dihydroxy-236HCB, which indicates that 4,5-dihydroxy-236HCB may be formed by a direct hydroxylation of 5-hydroxy-236HCB. The findings from this study demonstrate the importance of residues 114, 206, 209, 302, 363, 367, 477, 478, and 480 in 2B1 and 114, 290, and 363 in 2B11 for 236HCB metabolism.

Identification of three key residues in substrate recognition site 5 of human cytochrome P450 3A4 by cassette and site-directed mutagenesis.

Cassette mutagenesis and site-directed mutagenesis were used to investigate the importance of individual amino acid residues at positions 364-377 of cytochrome P450 3A4 in determining steroid hydroxylation or stimulation by alpha-naphthoflavone. The mutants were expressed in an Escherichia coli system, and solubilized membranes were prepared. All mutants except R365G and R365K exhibited anti-3A immunoreactivity on Western blotting, although R372S and R375K were not detected as the Fe2+-CO complex. Replacement of Arg-372 by Lys yielded a typical P450 spectrum. The results indicate that the highly conserved Arg residues at positions 365 and 375 may play a role in stabilizing the tertiary structure or in heme binding. Catalytic activities of 12 mutants were examined using progesterone and testosterone as substrates, and residues 369, 370, and 373 were found to play an important role in determining substrate specificity. Although the three mutants hydroxylated progesterone and testosterone primarily at the 6beta-position like the wild-type, replacement of Ile-369 by Val suppressed progesterone 16alpha-hydroxylase activity, whereas substitution of Ala-370 with Val enhanced progesterone 16alpha-hydroxylation. Interestingly, substitution of Leu-373 with His resulted in production of a new metabolite from both steroids. Moreover, the mutants at positions 369 and 373 were more and less responsive, respectively, than the wild-type to alpha-naphthoflavone stimulation. Alterations in activities or expression of several mutants were interpreted using a three-dimensional model of P450 3A4. The results suggest that analogy with mammalian family 2 and bacterial cytochromes P450 can be used to predict P450 3A residues that contribute to regiospecific steroid hydroxylation.

Functional interaction between amino-acid residues 242 and 290 in cytochromes P-450 2B1 and 2B11.

Previous studies have revealed the functional importance of the negatively charged amino-acid residue Asp-290 of the phenobarbital-inducible dog liver cytochrome P-450 (P-450) 2B11 (Harlow, G.R. and Halpert J.R. (1996) Arch. Biochem. Biophys. 326, 85-92). A search for P-450 2B11 residues capable of forming a charge pair with Asp-290 suggested the positively charged residue Lys-242 as a likely candidate. Replacement of Lys-242 with Asp in a P-450 2B11 fusion protein with rat NADPH-cytochrome P-450 reductase (reductase) resulted in very low holoenzyme expression levels in Escherichia coli, as did replacement of Asp-290 with Lys. Remarkably, however, expression levels of the double mutant Lys-242 --> Asp/Asp-290 --> Lys were dramatically increased above either single replacement alone. Similarly, the pair-wise substitutions Lys-242 --> Leu/Asp-290 --> Ile in P-450 2B11 and Leu-242 --> Lys/Ile-290 --> Asp in P-450 2B1 showed greater holoenzyme expression levels than the constituent single mutants, providing further evidence for the close proximity of these residues within the three-dimensional structure of these two enzymes. These results support the hypothesis that a functional interaction exists between residues 242 and 290, which may help to coordinate the relative positions of proposed helices G and I. All of the mutant combinations, including the additional P-450 2B11 double mutants Tyr-242/Asn-290 and Tyr-242/Ser-290, displayed altered stereoselectivity of androstenedione hydroxylation.

Secobarbital-mediated inactivation of cytochrome P450 2B1 and its active site mutants. Partitioning between heme and protein alkylation and epoxidation.

Secobarbital (SB) is a relatively selective mechanism-based inactivator of cytochrome P450 2B1, that partitions between epoxidation and heme and protein modification during its enzyme inactivation. The SB-2B1 heme adduct formed in situ in a functionally reconstituted system has been spectrally documented and structurally characterized as N-(5-(2-hydroxypropyl)-5-(1-methylbutyl)barbituric acid)protoporphyrin IX. The SB-protein modification has been localized to 2B1 peptide 277-323 corresponding to the active site helix I of cytochrome P450 101. The targeting of heme and this active site peptide suggests that the 2B1 active site topology could influence the course of its inactivation. To explore this possibility, the individual SB epoxidation, heme and protein modification, and corresponding molar partition ratios of the wild type and seven structural 2B1 mutants, site-directed at specific substrate recognition sites, and known to influence 2B1 catalysis were examined after Escherichia coli expression. These studies reveal that Thr-302 is critical for SB-mediated heme N-alkylation, whereas Val-367 is a critical determinant of 2B1 protein modification, and Val-363 is important for SB epoxidation. SB docking into a refined 2B1 homology model coupled with molecular dynamics analyses provide a logical rationale for these findings.

Role of residue 480 in substrate specificity of cytochrome P450 2B5 and 2B11.

The role of residue 480 as a determinant of the specificities of cytochrome P450 2B5 and 2B11 toward androstenedione, progesterone, 2,2',4,4',5,5'-hexachlorobiphenyl (245-HCB), and benzyloxyresorufin has been investigated. Two reciprocal mutants at position 480, 2B5 Val-480 -> Leu and 2B11 Leu -> Val, two hybrid enzymes, H1B (amino acid residues 1-370 from P450 2B11, 371-491 from P450 2B5) and H2B (amino acid residues 1-370 from P450 2B5, 372-494 from P450 2B11) (Kedzie et al., 1993, Biochim. Biophys. Acta 1164, 124-132), and two hybrid back mutants, H1B Val-480 -> Leu and H2B Leu-480 -> Val, were constructed and expressed in Escherichia coli, and compared with the wild-type enzymes P450 2B5 and 2B11. For androstenedione metabolism, the Leu-480 -> Val mutation in P450 2B11 resulted in an increase in the 16 beta-OH:16 alpha-OH ratio from 1.2 to 3, whereas the Val-480 -> Leu mutation in hybrid H1B decreased the 16 beta-OH:16 alpha-OH ration from 4.2 to 1.1 In the case of progesterone, the Leu-480 -> Val mutant of P450 2B11 displayed 3-fold higher 16 alpha- and 21-hydroxylase activities than the wild-type 2B11. In the absence of cytochrome b5, 2B11 L480V displayed half of the benzyloxyresorufin O-dealkylase (BROD) activity of 2B11 wild-type, whereas H1B V480L showed 5,6-fold higher activity than H1B. Therefore, residue 480 seems to play an important role in steroid and benzyloxyresorufin metabolism by P450 2B11. In contrast, the mutation Leu-480 -> Val did not have a significant effect on the 245-HCB hydroxylase activity of P450 2B11, and the mutation Val-480 -> Leu in P450 2B5 had no notable effect on its progesterone hydroxylase activity. Cytochrome b5 caused marked stimulation of the BROD activity of P450 2B11 and H1B and their mutants. Furthermore, P450 2B5 exhibited different progesterone metabolite profiles in the absence or presence of cytochrome b5.

Site-directed mutagenesis as a tool for molecular modeling of cytochrome P450 2B1.

Prompted by our previous homology model of cytochrome P450 2B1 based on the 3-D structure of P450cam [Szklarz, G. D., Ornstein, R. L., & Halpert, J. R. (1994) J. Biomol. Struct. Dyn. 12, 61-78], we constructed 11 new site-directed mutants at positions 100, 111, 205, 209, 291, 477, and 480 and expressed the enzymes in Escherichia coli. The mutations at positions 209, 477, and 480 affected androstenedione and progesterone hydroxylation as predicted by the model. For example, the Ile-477-->Ala and Ile-480-->Ala mutants retained < or = 5% activity with androstenedione and progesterone but were active with benzphetamine, whereas the Leu-209-->Ala mutant catalyzed 21-hydroxylation of progesterone. Mutations at the other positions, i.e., 100, 111, 205, and 291, did not change enzyme activity, contrary to predictions. Therefore, an improved molecular model of cytochrome P450 2B1 was constructed. An alignment of the P450 2B1 sequence with P450 BM-3, P450cam, and P450terp was optimized using data from site-directed mutagenesis at 27 positions in various cytochromes P450 2B and docking of androstenedione into the active site of the known crystal structures. Because all three structures were found to be suitable templates for P450 2B1, the new model was formulated on the basis of the crystallographic coordinates of the three proteins using a consensus strategy, a modeling method based on distance geometry calculations. The new model provides a means to explain alterations in regio- and stereospecificity of steroid hydroxylation upon residue substitution at key amino acid positions, including positions 114, 206, 209, 290, 302, 363, 367, 477, 478, and 480 in P450 2B1.

Escherichia coli expression of site-directed mutants of cytochrome P450 2B1 from six substrate recognition sites: substrate specificity and inhibitor selectivity studies.

Cytochrome P450 2B1 wild-type and eight site-directed mutations at positions 114, 206, 236, 302, 363, 367, and 478 have been expressed in an Escherichia coli system. Solubilized membrane preparations yielded 100-180 nmol of P450/L of culture. The metabolism of a number of substrates including androstenedione, progesterone, (benzyloxy)resorufin, pentoxyresorufin, and benzphetamine was analyzed. The E. coli-expressed enzymes displayed the same androstenedione metabolite profiles previously observed with a COS cell expression system. Several of the mutants exhibited an increased rate of progesterone hydroxylation, possibly as the result of an enlarged substrate binding pocket and increased D-ring alpha-face binding. (Benzyloxy)resorufin and pentoxyresorufin O-dealkylation by the P450 2B1 mutants exhibited activities ranging from 10% to 99% and 3% to 71% of wild-type, respectively. Interestingly, the Val-363-->Leu mutant showed markedly suppressed pentoxyresorufin but unaltered (benzyloxy)resorufin dealkylase activity. Benzphetamine N-demethylase activities ranged from 28% to 110% of wild-type. Mechanism-based inactivation of the P450 2B1 mutants showed that susceptibility to inactivation by chloramphenicol and D-erythro- and L-threo-chloramphenicol was abolished in the Val-367-->Ala mutant. The Val-363-->Leu mutant was refractory to L-threo-chloramphenicol. Studies of chloramphenicol covalent binding and metabolism by the Val-367-->Ala mutant showed that its resistance to inactivation is largely attributable to an inability to bioactivate the inhibitor. The expression of P450 2B1 wild-type and mutants in E. coli provides an excellent opportunity to study structure/function relationships by site-directed mutagenesis.

Escherichia coli expression and characterization of cytochromes P450 2B11, 2B1, and 2B5.

Dog CYP2B11, rat CYP2B1, and rabbit CYP2B5 have been expressed in Escherichia coli from cDNAs modified at the N-terminus (Barnes et al., 1991, Proc. Natl. Acad. Sci. USA 88, 5597-5601). Using 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (Chaps), solubilized membranes representing > 100 nmol of P450 2B11, > 35 nmol of P450 2B1, and > 7 nmol of P450 2B5 were efficiently extracted (40-70% yield) from a 1-liter culture. Chaps-solubilized preparations produced a reduced CO/reduced difference spectrum devoid of P420 and were used directly in a reconstituted system. The E. coli-expressed 2B enzymes retained the same functional characteristics as the purified hepatic enzymes or enzymes expressed in COS cells in terms of androstenedione metabolite profiles. Hydroxylation rates were determined under a variety of conditions, including two concentrations of NADPH-cytochrome P450 reductase (2 and 16 nmol/nmol P450) and the absence or presence of cytochrome b5 (2 nmol/nmol P450). The androstenedione hydroxylase activities of expressed 2B1 and 2B5 were stimulated by cytochrome b5, whereas P450 2B11 was inhibited slightly by cytochrome b5. Purified expressed 2B11 (specific content, 8 nmol/mg protein) had similar activities as the Chaps-solubilized membrane preparation. The solubilized membranes containing 2B11 were also tested with 2,2',4,4',5,5'-hexachlorobiphenyl (245-HCB). Three major metabolites, 2-hydroxy-4,5,2',4',5'-pentachlorobiphenyl, 3-hydroxy-2,4,5,2',4',5'-hexachlorobiphenyl, and 2-hydroxy-3,4,5,2',4',5'-hexachlorobiphenyl were produced from 245-HCB. These metabolites are identical to those produced by 2B11 purified from liver microsomes. The 245-HCB hydroxylation rates were similar for E. coli-expressed 2B11, dog liver microsomes, and purified liver 2B11. When only the second codon in the 2B1 was changed to GCT, > 25 nmol of P450 was extracted from a 1-liter culture, suggesting that the full Barnes et al. modification scheme may not be necessary for high-level expression. An efficient method of expressing, extracting, and analyzing different P450 2B enzymes has thus been achieved. In addition, rabbit P450 2B5, which has never been purified from liver, as well as different P450 2B mutants can now be expressed at much higher levels than previously reported. The ability to express different 2B wild-type and mutant P450s in E. coli provides an excellent opportunity to study the molecular basis of species differences in substrate metabolism.

Site-directed mutagenesis of putative substrate recognition sites in cytochrome P450 2B11: importance of amino acid residues 114, 290, and 363 for substrate specificity.

Eleven amino acid residues unique to dog cytochrome P450 (P450) 2B11, compared with rat 2B1 and 2B2, rabbit 2B4 and 2B5, and mouse 2B10, in the putative substrate recognition sites [J. Biol. Chem. 267:83-90 (1992)] were mutated to the residues found in 2B1 or 2B5. The mutants were expressed initially in COS cells and screened for activity toward androstenedione and 2,2',4,4',5,5'-hexachlorobiphenyl (245-HCB). P450 2B11 mutants V107I, M199L-N200E-V204R, V234I, A292L, Q473R, and I475S showed no differences from wild-type P450 2B11 in metabolite profiles with either substrate. Mutants V114I, D290I, and L363V exhibited altered androstenedione metabolite profiles and were expressed in Escherichia coli for further study with androstenedione, testosterone, 7-ethoxycoumarin, (R)- and (S)-warfarin, and 245-HCB. With V114I, hydroxylation of steroids and warfarin and 2-hydroxylation of 245-HCB were decreased, whereas 7-ethoxycoumarin O-dealkylation and 3-hydroxylation of 245-HCB were unaltered. For D290I, activities toward all substrates were decreased, except for 16 beta-hydroxylation of testosterone. The activity of L363V was increased 5-6-fold for 16 alpha-hydroxylation of androstenedione and testosterone but was decreased to 40-50% of wild-type activity with 7-ethoxycoumarin and warfarin and to 6-8% of control for 2-hydroxylation of 245-HCB. Alignment of P450 2B11 with P450 101 and super-imposition of the 11 mutated 2B11 residues on a P450 101 three-dimensional model suggest that only residues 114, 290, and 363 represent substrate contact residues, in excellent agreement with the experimental results. The data indicate the importance of the three residues 114, 290, and 363 in substrate specificity and regio- and stereoselectivity of P450 2B11 and also demonstrate that the effects of the mutations vary considerably with different substrates.

Role of residues 363 and 206 in conversion of cytochrome P450 2B1 from a steroid 16-hydroxylase to a 15 alpha-hydroxylase.

Four double and four triple site-directed mutants of cytochrome P450 2B1 were constructed, expressed in COS cells, and assayed for androstenedione and testosterone hydroxylation. The mutants combined a Val-363-->Ala substitution with an Ile-114-->Val or Ala substitution and/or a Gly-478-->Ala or Ser substitution. Each of the individual mutations enhances androgen 15 alpha-hydroxylation, and the appropriate combination of Val or Ala at position 114 with Ala or Ser at position 478 has recently been shown to convert P450 2B1 from an androstenedione and testosterone 16 beta-hydroxylase to a 15 alpha-hydroxylase (Halpert, J. R., and He, Y.-A. (1993) J. Biol. Chem. 268, 4453-4457). All eight mutants containing the Val-363-->Ala substitution preferentially hydroxylated androstenedione and testosterone in the 15 alpha-position and thus functionally resemble mouse P450 2A4. However, unlike P450 2A4, various single and multiple 2B1 mutants at positions 114, 363, and 478 mainly hydroxylated progesterone in the 16 alpha- rather than 15 alpha-position. By combining the Ile-114-->Ala substitution with a Phe-206-->Leu mutation (corresponding to Ala-117 and Leu-209 in P450 2A4), P450 2B1 was converted to a progesterone 15 alpha-hydroxylase with retention of testosterone 15 alpha-hydroxylase activity. These studies document the importance of residues 363 and 206 in determining the substrate specificity of P450 2B1 and strongly support the hypothesis that the judicious combination of a small number of discrete mutations can be used to confer new specificities on P450 enzymes.

Engineering of cytochrome P450 2B1 specificity. Conversion of an androgen 16 beta-hydroxylase to a 15 alpha-hydroxylase.

Six site-directed mutants of cytochrome P450 2B1 were constructed, and function was evaluated in COS cell microsomes by monitoring testosterone and androstenedione hydroxylation and inactivation by chloramphenicol. Mutants Ile-114-->Val and Ile-114-->Ala exhibited marked decreases in androgen 16 beta-OH:16 alpha-OH ratios and increases in 15 alpha-OH:16-OH ratios. Since substitution of Gly-478 with Ala or Ser reduces 16 beta-hydroxylation in favor of 15 alpha-hydroxylation, four double mutants containing Val or Ala at position 114 and Ala or Ser at position 478 were examined. For any given residue at position 114 (Ile, Val, or Ala), the 15 alpha-OH:16-OH ratio increased as residue 478 was changed from Gly to Ala to Ser, and for any residue at position 478, this ratio increased as residue 114 was changed from Ile to Val to Ala. As a consequence, the Ile-114-->Ala, Gly-478-->Ser mutant displayed an approximately 1000-fold higher androgen 15 alpha-OH:16-OH ratio compared with the parental enzyme and functionally resembles mouse P450 2A4 much more closely than P450 2B1. All three mutants with Val at position 114 retained susceptibility to inactivation by chloramphenicol, whereas inactivation was suppressed by Ala at this position. The results suggest the feasibility of an empirical approach to P450 engineering involving the appropriate combination of residues at a few critical sites to confer new regio- and stereoselectivity with retention of overall monooxygenase activity.

Role of residue 478 as a determinant of the substrate specificity of cytochrome P450 2B1.

Two allelic variants and eight site-directed mutants of cytochrome P450 2B1 differing at residue 478 have been expressed in COS cells and assayed for androstenedione hydroxylase activities. The 478Gly and 478Ala variants and five mutants (Ser, Thr, Val, Ile, and Leu) exhibited 16 beta-OH:16 alpha-OH ratios ranging from 0.7 to 9.3, whereas the Pro, Glu, and Arg mutants were expressed but inactive. The seven samples active toward androstenedione also exhibited testosterone 16 beta-OH:16 alpha-OH ratios ranging from 0.4 to 2.3. With both steroids, the Gly variant had the highest 16 beta-hydroxylase activity, and the 16 beta-OH:16 alpha-OH ratio increased with the size of aliphatic size chains (Ala, Val, and Ile/Leu). The highest ratio of androgen 15 alpha:16-hydroxylation was observed with the Ser mutant. On the basis of previous work indicating decreased susceptibility of the 478Ala variant in liver microsomal and reconstituted systems to inactivation by chloramphenicol analogs, methodology was refined for monitoring enzyme inactivation in COS cell microsomes. The Gly and Ala variants were inactivated by chloramphenicol with similar rate constants, whereas the Ser and Val mutants were inactivated more slowly, and the Leu mutant was refractory. Only the Gly variant was inactivated by the chloramphenicol analog N-(2-p-nitrophenethyl)chlorofluoroacetamide. Thus, the side chain of residue 478 appears to be a major determinant of enzyme inactivation as well as of androgen hydroxylation.(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular basis for a functionally unique cytochrome P450IIB1 variant.

Liver microsomes from phenobarbital-treated rats of four inbred strains expressing distinct allelic variants of cytochrome P450IIB1 were analyzed. The Wistar Munich (WM) strain exhibited 5- to 10-fold lower androstenedione 16 beta-hydroxylase activity (a specific P450IIB1 marker) than the Lewis, Wistar Kyoto, and Wistar Furth strains. The androstenedione 16 beta-hydroxylase in the WM liver microsomes was refractory to inactivation by N-(2-p-nitrophenethyl)chlorofluoroacetamide, a selective P450IIB1 inactivator in the other three strains. Purified P450IIB1-WM was insensitive to the inactivator and exhibited 5-fold lower androstenedione 16 beta-hydroxylase, testosterone 16-hydroxylase, and 7-ethoxycoumarin deethylase activities but the same benzphetamine demethylase activity and slightly higher androstenedione 16 alpha-hydroxylase activity than a P450IIB1 purified from outbred Sprague-Dawley rats, which appears to correspond to the form in Lewis rats. The stereoselectivity of androstenedione 16-hydroxylation catalyzed by P450IIB1-WM (16 beta-OH:16 alpha-OH = 1.4) is thus distinct from that (16 beta-OH:16 alpha-OH = 12-15) of other P450IIB1 preparations described. A cDNA encoding P450IIB1-WM was cloned and sequenced, revealing a single amino acid substitution (Gly-478----Ala) compared with the published sequence (Fujii-Kuriyama, Y., Mizukami, Y., Kawajiri, K., Sogawa, K., and Muramatsu, M. (1982) Proc. Natl. Acad. Sci. U. S. A. 79, 2793-2797). Heterologous expression of P450IIB1 and P450IIB1-WM confirmed the striking difference in androstenedione metabolite profiles, strongly implicating the involvement of Ala-478 in defining the distinctive catalytic properties of P450IIB1-WM.

A Chinese familial growth hormone deficiency with a deletion of 7.1 kb of DNA.

Using restriction endonuclease analysis and a human growth hormone cDNA probe, we have found a Chinese family with a human growth hormone gene deletion. Two affected sibs are homozygous for a deletion of approximately 7.1 kb of DNA, which contains the normal human growth hormone gene. The patients' parents and grandmothers are heterozygous for the deleted gene. Their grandfathers are normal and homozygous for the hGH-N gene. All of them have normal stature.